A nanopore system provided herein includes first and second fluidic reservoirs in fluidic communication with a nanopore forming a fluidic path between the reservoirs. An enzyme clamp, provided in the first fluidic reservoir, abuts the nanopore and is reversibly bound to a sequential plurality of polymer subunits of a target polymer molecule in ionic solution. The clamp has an outer clamp diameter that is greater than the nanopore diameter. An electrical circuit includes an electrode in each of the reservoirs for applying a voltage bias across the nanopore. A pulse generator is connected in the electrical circuit to apply control pulses across the nanopore to step the clamp along sequential polymer subunits of the target polymer molecule. The system includes no fuel or source of fuel for the clamp. A controller is connected in the electrical circuit for controlling the collection of electrical indications of polymer subunits.

In a method p for controlling translocation of a target polymer molecule through a nanopore, a clamp is reversibly bound to a sequential plurality of polymer subunits along the target polymer molecule length and the molecule and clamp are disposed in an ionic solution that is in fluidic communication with the nanopore. A constant translocation force is applied across the nanopore to induce travel of the target polymer molecule into the nanopore, until the clamp abuts the nanopore aperture and stops further travel of the target polymer molecule into the nanopore. Then a voltage control pulse is applied across the nanopore and/or a thermal control pulse is applied at the nanopore, with a pulse duration that steps the clamp along the target polymer molecule by no more than one polymer subunit in a direction opposite that of travel into the nanopore. No fuel is provided to the clamp.

In a method p for controlling translocation of a target polymer molecule through a nanopore, a clamp is reversibly bound to a sequential plurality of polymer subunits along the target polymer molecule length and the molecule and clamp are disposed in an ionic solution that is in fluidic communication with the nanopore. A constant translocation force is applied across the nanopore to induce travel of the target polymer molecule into the nanopore, until the clamp abuts the nanopore aperture and stops further travel of the target polymer molecule into the nanopore. Then a voltage control pulse is applied across the nanopore and/or a thermal control pulse is applied at the nanopore, with a pulse duration that steps the clamp along the target polymer molecule by no more than one polymer subunit in a direction opposite that of travel into the nanopore. No fuel is provided to the clamp.

A nanopore system provided herein includes first and second fluidic reservoirs in fluidic communication with a nanopore forming a fluidic path between the reservoirs. An enzyme clamp, provided in the first fluidic reservoir, abuts the nanopore and is reversibly bound to a sequential plurality of polymer subunits of a target polymer molecule in ionic solution. The clamp has an outer clamp diameter that is greater than the nanopore diameter. An electrical circuit includes an electrode in each of the reservoirs for applying a voltage bias across the nanopore. A pulse generator is connected in the electrical circuit to apply control pulses across the nanopore to step the clamp along sequential polymer subunits of the target polymer molecule. The system includes no fuel or source of fuel for the clamp. A controller is connected in the electrical circuit for controlling the collection of electrical indications of polymer subunits.

A method is provided for deterministically translocating through a nanopore a target polymer molecule of a nucleic acid polymer molecule or a protein polymer molecule. In the method, an enzyme clamp is reversibly bound to a plurality of sequential polymer subunits of the target polymer molecule. The target polymer molecule and the enzyme clamp are disposed at the nanopore. In the method, there is applied a pulse of force operative to deterministically advance the enzyme clamp along the target polymer molecule by no more than one polymer subunit. The pulse of force is then repeatedly applied to cause deterministic translocation of a sequential plurality of polymer subunits of the target polymer molecule through the nanopore.

In a method for controlling translocation of a target polymer molecule through a nanopore, a clamp is reversibly bound at a site along the target polymer molecule length; the clamp and the target polymer molecule are disposed in an ionic solution that is in fluidic communication with a nanopore having an aperture diameter less than an outer diameter of the clamp. A constant translocation force is applied across the nanopore to induce travel of the target polymer molecule into the nanopore such that the reversibly bound clamp abuts the nanopore. A voltage pulse is applied across the nanopore that advances the target polymer molecule into the nanopore by one nucleotide, without either of chemical fuel and biochemical fuel provided to the clamp. The voltage pulse is repeatedly applied to cause a plurality of nucleotides to translocate through the nanopore. An indication of each nucleotide can be acquired during nucleotide translocation.

In a method for controlling translocation of a target polymer molecule through a nanopore, a clamp is reversibly bound at a site along the target polymer molecule length; the clamp and the target polymer molecule are disposed in an ionic solution that is in fluidic communication with a nanopore having an aperture diameter less than an outer diameter of the clamp. A constant translocation force is applied across the nanopore to induce travel of the target polymer molecule into the nanopore such that the reversibly bound clamp abuts the nanopore. A voltage pulse is applied across the nanopore that advances the target polymer molecule into the nanopore by one nucleotide, without either of chemical fuel and biochemical fuel provided to the clamp. The voltage pulse is repeatedly applied to cause a plurality of nucleotides to translocate through the nanopore. An indication of each nucleotide can be acquired during nucleotide translocation.